Method and system for a single frequency network for broadcasting to mobile devices

ABSTRACT

One or more circuits of a satellite reception assembly may be operable to receive a satellite signal, recover content carried in the satellite signal, and broadcast a signal carrying the content for reception by one or more mobile devices. The satellite reception assembly may be mounted to the residence of a satellite subscriber. The signal carrying the content may be frequency locked to a reference signal that is available to the satellite reception assembly and to one or more other satellite reception assemblies. The reference signal may be a GNSS signal. The one or more circuits may communicate with the one or more mobile devices to provide a key to the one or more mobile devices, where the key is required for descrambling and/or decryption of the content carried in said signal.

CLAIM OF PRIORITY

This patent application is a continuation of U.S. patent applicationSer. No. 13/591,768 filed on Aug. 22, 2012 (now U.S. Pat. No.9,008,571).

INCORPORATION BY REFERENCE

This patent application makes reference to:

U.S. provisional patent application Ser. No. 61/620,720 entitled “Methodand System for Full Spectrum Capture (FSC) for Terrestrial Applications”and filed on Apr. 5, 2012;U.S. provisional patent application Ser. No. 61/595,654 entitled “Methodand System for an Internet Protocol LNB (IP LNB)” and filed on Feb. 6,2012, now expired;United States patent application publication no. 20120297427 entitled“System and Method in a Broadband Receiver for Efficiently Receiving andProcessing Signals” and filed on Dec. 14, 20122;United States patent application publication no. 20120297414 entitled“System and Method for Conditional Access in an In-Home Network Based onMulti-Network Communication” and filed on Dec. 12, 2011;U.S. Pat. No. 8,466,850 entitled “Method and System for Multi-ServiceReception” and filed on Jul. 11, 2012;U.S. Pat. No. 8,929,728 entitled “Method and Apparatus for ContentProtection and Billing for Mobile Delivery of Satellite Content” andfiled on Aug. 15, 2012; andUnited States patent application publication no. 20140057555 entitled“Method and System for Caching Content for Mobile Distribution” filed onAug. 22, 2012.

Each of the applications listed above is hereby incorporated herein byreference in its entirety.

TECHNICAL FIELD

Aspects of the present application relate to electronic communications.More specifically, to a method and system for a single frequency networkfor broadcasting to mobile devices.

BACKGROUND

Existing methods and systems for delivering terrestrial and/or satellitebroadcast content to mobile devices can be inefficient. Furtherlimitations and disadvantages of conventional and traditional approacheswill become apparent to one of skill in the art, through comparison ofsuch approaches with some aspects of the present method and system setforth in the remainder of this disclosure with reference to thedrawings.

BRIEF SUMMARY

A method and/or system is provided for a single frequency network forbroadcasting to mobile devices, substantially as illustrated by and/ordescribed in connection with at least one of the figures, as set forthmore completely in the claims.

BRIEF DESCRIPTION OF THE DRAWINGS

FIGS. 1A and 1B depict a system that is operable to broadcast data tomobile devices.

FIG. 2 depicts an example implementation of the system of FIG. 1 inwhich the system comprises a small-cell base station.

FIG. 3 depicts an example implementation of the system of FIG. 1 inwhich the system comprises a macrocell basestation.

FIG. 4A is a diagram depicting a region of a single frequency networkfor broadcasting to mobile devices.

FIG. 4B is a diagram depicting multiple regions of a single frequencynetwork for broadcasting to mobile devices.

FIG. 5 is a flowchart illustrating example steps for delivering data tomobile devices via a single frequency network.

FIG. 6 is a block diagram of an example mobile device operable toreceive data broadcast on a single frequency network.

FIG. 7 is a flowchart illustrating example steps for delivery of contentto a mobile device via a single frequency network.

FIG. 8 depicts a plurality of satellite reception assemblies that areoperable to participate in a single frequency network.

DETAILED DESCRIPTION

As utilized herein the terms “circuits” and “circuitry” refer tophysical electronic components (i.e. hardware) and any software and/orfirmware (“code”) which may configure the hardware, be executed by thehardware, and or otherwise be associated with the hardware. As utilizedherein, “and/or” means any one or more of the items in the list joinedby “and/or”. As an example, “x and/or y” means any element of thethree-element set {(x), (y), (x, y)}. As another example, “x, y, and/orz” means any element of the seven-element set {(x), (y), (z), (x, y),(x, z), (y, z), (x, y, z)}. As utilized herein, the term “module” refersto functions than can be performed by one or more circuits. As utilizedherein, the term “exemplary” means serving as a non-limiting example,instance, or illustration. As utilized herein, the terms “e.g.,” and“for example” introduce a list of one or more non-limiting examples,instances, or illustrations.

FIGS. 1A and 1B depict a system that is operable to broadcast data tomobile devices. Referring to FIG. 1A, the system 100 comprises abroadcast receive module 104, a wireless input/output (I/O) module 106,a wired I/O module 108, and a routing module 124. Also shown are aservice provider network 131, a mobile device 110, a module 112, aclient device 122, and a wide area network (WAN) 120.

The satellite 102 may broadcast data (e.g., media content) in accordancewith a broadcast standard such as, for example, DVB-S. In an exampleimplementation, some of the bandwidth of the satellite 102 may beutilized for transmitting mobile-formatted content. For example, thecontent of one or more television networks may be concurrently broadcastin a first format (e.g., high-definition, low-compression ratio videoand surround-sound audio) a second format (e.g., standard definition,high-compression ration video and stereo audio). The first format may beencrypted and/or scrambled utilizing a first content protection scheme(e.g., a first set of security algorithms and/or a first set of keysand/or certificates) and the second format may be encrypted and/orscrambled utilizing a second content protection scheme (e.g., a firstset of security algorithms and/or a first set of keys and/orcertificates). For example, content protected with the first scheme maybe recoverable only by devices (e.g., gateways) that have built-inhardware-based conditional access systems (CAS), whereas contentprotected with the second scheme may be recoverable utilizing keysobtained through two-way exchanges.

The network 131 represents the network(s) of one or more serviceproviders. For example, the network 131 may comprise a network of acellular service provider, a network of a satellite service provider,and/or a network of a billing service provider that performs billingfunctions for other service providers. The security and/or billingserver 130 may manage billing accounts for subscribers of one or moreservice providers. For example, the server 130 may maintain a databaseof users and/or mobile devices which are subscribed to content that isbroadcast by the satellite 102 and delivered in a unicast and/ormulticast manner via the WAN 120, and may track consumption of thecontent by those users/devices. This information may be provided to asatellite service provider so that the satellite provider can bill theusers/devices for the content. Similarly, the server 130 may maintain adatabase of users and/or mobile devices which are subscribed to wireless(e.g., cellular) services associated with the wireless module 106 andmay track usage of the module 106's bandwidth. This information may beprovided to a cellular service provider so that the cellular providercan bill the users/devices for the bandwidth usage.

Additionally or alternatively, the security and/or billing server 130may manage certificates, keys, and/or other security information foraccessing content broadcast by the satellite 102 and/or delivered to thesystem 100 via the WAN 120 and broadband connection 126. For example,the server 130 may maintain a database of content currently beingtransmitted to the system 100 and keys and/or other security informationassociated with that content. In the example implementation shown inFIG. 1A, the system 100 communicates with the server 130 via the WAN120. In the implementation shown in FIG. 1B, on the other hand, theserver 130 is reachable wirelessly, via wireless I/O module 132, suchthat the system 100 can communicate with the server 130 via a connection134 without use of the WAN 120 or broadband connection 126.

The mobile device 110 may be operable to communicate wirelessly inaccordance with one or more wireless communication protocols. Forexample, the device 110 may be a cellular handset operable tocommunicate in accordance with cellular (e.g., LTE) and/or IEEE 802.11protocols. An example implementation of the mobile device 110 isdescribed below with reference to FIG. 6.

The various components of the system 100 and the module 112 may becollocated on, for example, a cellular tower as shown in FIG. 3 or asatellite subscriber premises (e.g., a house, multi-dwelling unit, orbusiness) as shown in FIG. 2. The system 100 may comprise one or moreprinted circuit boards and/or one or more integrated circuits (e.g., oneor more silicon die).

The system 100 and the module 112 may be part of a local area network(LAN) and may be interconnected via a LAN technology such as Ethernet(e.g., Ethernet frames communicated over an Ethernet physical layer suchas 10/100/1G/10G/40GBASE-T). In an example implementation, each port ofthe system 100 and the port of module 112 that connects to system 100may share a common subnet address that is not shared with the port ofthe module 112 that connects to the WAN 120. The module 112 mayinterface the LAN to a wide area network (WAN) 120 over broadbandconnection 126 utilizing, for example, DOCSIS, DSL, Carrier Ethernet,ATM, Frame Relay, ISDN, x.25, and/or other suitable WAN technology. TheWAN 120 may, for example, backhaul traffic between wireless I/O module106 and a cellular core network.

The broadcast (e.g., satellite broadcast) receive module 104 may beoperable to receive broadcast signals and process the received broadcastsignals to recover data (e.g., audio content, video content, and/orauxiliary data related to audio and/or video content) carried therein.Although this disclosure focuses on satellite radio and satellitetelevision broadcast signals, the present invention is not so limited.Rather, other types of signals such as terrestrial broadcast televisionsignals are contemplated. Accordingly, various implementations of thesystem 100 may comprise features described in U.S. Pat. No. 8,466,850,which is incorporated herein by reference, as set forth above. In anexample implementation, the receive module 104 may performchannelization such that specific channels, streams, programs, etc. fromthe receive module 104 can be selectively conveyed to the routing module124. In an example implementation, the receive module 104 may outputdata in the form of MPEG transport stream(s) to the routing module 124.In an example implementation, the receive module 104 may encapsulatereceived data utilizing one or more protocols (e.g., Internet Protocol)for output to the routing module 124.

The wireless module 106 may be operable to engage in unicast and/ormulticast communications with user equipment as represented by theconnection 116. The wireless module 106 may be operable to engage inunicast and/or multicast communications with a service provider, asrepresented by connection 134. The wireless module 106 may be operableto broadcast data (e.g., media content), as represented by signal 136.The wireless module 106 may transmit and/or receive utilizing one ormore wireless communication protocols such as, for example, cellular(e.g., LTE) and/or IEEE 802.11 protocols. In various exampleimplementations, the wireless module 106 may transmit and/or receiveutilizing frequency spectrum owned and/or licensed by a cellularprovider, utilizing unlicensed frequency spectrum (e.g., in anIndustrial, Scientific, and Medical (ISM) band) and/or utilizingdedicated frequency spectrum owned and/or licensed by the satelliteprovider affiliated with the satellite 102. In an exampleimplementation, data may be communicated between the wireless module 106and the routing module 124 in the form of MPEG transport stream (TS)packets. In an example implementation, data may be communicated betweenthe wireless module 106 and the routing module 124 in the form ofInternet Protocol (IP) packets.

In an example implementation, the wireless module 106 may comprise atiming reference module 128 which may enable the wireless module 106 tosynchronize timing of its transmissions to a reference clock and/orfrequency of its transmissions to a frequency reference signal. Forexample, the timing reference module 128 may be operable to synchronizeto a reference clock and/or frequency reference signal present inreceived global navigation satellite system (GNSS) signals.

The wired module 108 may be operable to communicate data, via one ormore cables 114, with module 112. The module 112 (e.g., a media gatewayand/or edge router) may, in turn, route traffic between the system 100and one or more other devices (e.g., client devices, such as client 122,connected to the gateway and/or interior network nodes connected to thegateway). In an example implementation, the wired I/O module 108 may beoperable to output, onto the cable(s) 114, L-band signals received fromthe receive module 104. Such signals may be output in instances that themodule 112 is a legacy gateway. Additionally or alternatively, the wiredmodule 108 may be operable to communicate over the cable(s) 114utilizing Ethernet, Multimedia over Coax Alliance (MoCA), and/or anyother suitable protocol(s). In this manner, content may be delivered tothe system 100 via the WAN 120 and broadband connection 126. Suchcommunications may be used, for example, when the module 112 is agateway that is compatible with an IP-LNB as described in U.S. patentapplication Ser. No. 13/326,125, which is incorporated by referenceherein as set forth above.

In another example implementation, the module 112 may support a wirelessconnection and the functionality of the wired module 108 may be subsumedby the wireless module 106 and/or by a second wireless module.

The routing module 124 may be operable to selectively route data and/orsignals between the modules 104, 106, and 108. The routing may be based,for example, on IP addresses, TCP/UDP port numbers, packet identifiers(PIDs), stream identifiers, and/or any other suitable field orinformation. For example, packets comprising a first PID (e.g., packetscarrying mobile-formatted content) may be sent to the wireless module106 and packets comprising a second PID (e.g., packets carryinghigh-definition content) may be sent to the wired module 108. In anexample implementation, the routing module 124 may be a digital and/oranalog crossbar. In an example implementation, the routing module 124may perform an OSI layer-3 packet-routing function and/or an OSI layer-2packet-switching function. The routing module 124 may be configured viaone or more control signals (not shown) which may, in turn, be based oninput (e.g., utilizing a protocol such as DiSEqC) from the module 112and/or client devices such as the client device 122 and client device110.

In operation of an example implementation, the broadcast receive module104 may receive a satellite signal and perform block down conversion togenerate an L-band signal. The L-band signal may be conveyed to thewired module 108 for support of legacy gateways. The receive module 104may also demodulate the L-band signal to recover one or more MPEGtransport streams, channelize the transport stream(s) to recover one ormore programs, and encapsulate the transport stream(s) and/or program(s)into one or more packet streams (e.g., utilizing IP or some othersuitable protocol(s)). Typically, operations such as encryption,decryption, descrambling, scrambling, etc. may be performed in endsystems such as the server serving media content and the end-user deviceconsuming the content. In some instances, however, the receive module104 may be operable to decrypt, encrypt, descramble, and/or scramblerecovered transport stream(s)/program(s) as described in U.S. patentapplication Ser. No. 13/316,796, which is incorporated by referenceherein as set forth above. The one or more packet streams may beconveyed, via routing module 124, to the wireless module 106 and/or thewired module 108.

The wired module 108 may decapsulate, encode, modulate, encrypt, and/orotherwise process the transport stream(s) to generate signals suitablefor transmission via the cable(s) 114. The wired module 108 may transmitthe generated signals via the cable(s) 114. Additionally, the wiredmodule 108 may receive signals via the cable(s) 114, decapsulate,encode, modulate, encrypt, and/or otherwise process the signals torecover content carried in the signals that may have originated from themodule 112 and/or been received via the WAN 120 and the broadbandconnection 126. The wired module 108 may encapsulate the content into apacket stream and convey the packet stream to the routing module 124.

The wireless module 106 may encode, modulate, and/or otherwise processpacket stream(s) received from the routing module 124 to generatesignals suitable for broadcast by the basestation 226. Thus, the system100 may enable broadcast of satellite data and/or data delivered to thesystem 100 via the WAN 120 and broadband connection 126. For the datareceived from the satellite 120, the system 100 may enable deliveringthe data to the mobile device 110 without the data having to traversethe WAN 120 or the broadband connection 126. The wireless module 106 mayalso convey information about the mobile device 110, and informationabout the data consumed by the mobile device 110, to the server 130 forpurposes of billing and/or usage tracking.

Broadcasts of data by the wireless module 106 may be synchronized via,the timing reference module 128, to a received reference clock and/orfrequency reference signal. In this manner, the wireless module I/O 106may be operable to broadcast particular data at the same time and on thesame frequency band that the same data is being broadcast by othertransmitters (e.g., other instances of the system 100). The system 100along with the other transmitters may thus form a single-frequencybroadcast network (SFN). As utilized herein, “single frequency” networkrefers to the fact that particular data may be simultaneously (or nearlyso) transmitted by multiple transmitters on the same frequency. Eachtransmitter, however, is not limited to broadcasting on only a singlefrequency. Rather, each transmitter may broadcast data on multiplefrequencies. Each transmitter that is part of the SFN may adhere to anelectronic programming guide (EPG) that is distributed, for example, viathe satellite 102 and/or the server 130. The EPG may establish whichdata should be broadcast on which frequency band. In an exampleimplementation, the EPG may assign content and frequency bands on aregion-by-region basis such that transmitters in a particular regioneach broadcast the same data on the same frequency. In this manner, to adevice 110 roaming around a particular geographic region, the signalsfrom the various transmitters in the region may simply appear, and beprocessed, as if they are multipath signals from a single transmitter.Different frequency bands may be utilized in different regions to, forexample, account for different spectrum availability in the differentregions.

FIG. 2 depicts an example implementation of the system of FIG. 1 inwhich the system comprises a basestation, such as, for example, asmall-cell (e.g., femtocell or picocell) base station. In FIG. 2, thesystem 100 comprises a satellite reception assembly 202, and a gateway214. The subassembly 204 comprises a feed horn 212, an IP-LNB module224, a cellular basestation module 226, a routing module 230, anEthernet transceiver module 228, and a wireless transceiver 232. Thevarious modules of the subassembly 204 may reside in one or morehousings, on one or more printed circuit boards, and/or on one or moreintegrated circuits (e.g., one or more silicon dice). The satellitereception assembly is not limited to implementations comprising a dish.For example, another implementation of the satellite reception assembly204 may comprise a linear or parabolic array of antenna elements and/orreceiver circuits whose signals may be combined for satellite signalreception.

In the example implementation depicted, the satellite reception assembly202 comprises a parabolic reflector 206 and a subassembly 204 mounted(e.g., bolted or welded) to a support structure 208 which, in turn,comprises a boom 220 and attaches (e.g., via bolts) to the premises 210(e.g., to the roof). In another example implementation, all or a portionof the modules 224, 226, 228, 230, and 232 may be mounted to thepremises separate from the satellite reception assembly (e.g., connectedvia wired and/or wireless connections), but may still be part of the“outdoor unit.” In another example implementation, all or a portion ofthe modules 224, 226, 228, 230, and 232 may be part of the gateway 214(or “indoor unit”).

The IP-LNB module 224 may be an implementation of the receive module 104described above and may be as described in U.S. patent application Ser.No. 13/326,125, which is incorporated herein by reference, as set forthabove. The nomenclature “IP-LNB” indicates that the module 224 possessescapabilities beyond the block downconversion of received satellitesignals that is performed by conventional LNBs. Functions performed bythe IP-LNB module 224 may comprise, for example, downconverting receivedsatellite signals, demodulating received satellite signals, channelizingreceived satellite signals, and/or encapsulating data recovered fromreceived satellite signals into IP packets.

The routing module 230 may be an implementation of the routing module124 described above. Functions performed by the routing module 230 maycomprise routing of data between the IP-LNB module 224, the cellularbasestation module 226, and the Ethernet transceiver module 228.Although an implementation in which the routing module supports IP-basedrouting is described herein, any suitable protocols (e.g., Ethernet,PCIe, USB, etc.) can be utilized for communication of data betweenmodules 224, 226, 228, 230, and 232.

The Ethernet transceiver module 228 may be an implementation of thewired module 108 described above. Functions performed by the module 228may comprise encapsulation of data from the routing module 230 intoEthernet frames and transmission of the Ethernet frames onto thecable(s) 114 in accordance with Ethernet protocols. Additionally oralternatively, functions performed by the module 228 may comprisereception of Ethernet frames via the cable(s) 114, processing of theEthernet frames to recover data carried therein (e.g., IP packets), andconveyance of the recovered data to the routing module 230.

The combination of the small-cell basestation module 226 and thewireless module 232 may be an implementation of the wireless module 106described above. Functions performed by the basestation module 226 maycomprise communication with cellular-enabled user-equipment (e.g.,handsets, tablets, and/or laptops) that are within communication rangeof the basestation 226. The basestation module 226 may be operable toreceive data via one or more cellular connections 116, process thereceived data, and output the data to the routing module 230 in the formof one or more IP packets. Similarly, the small-cell basestation 226 maybe operable to receive IP packets from the routing module 230, processthe IP packets, and transmit signals carrying the IP packets (or theircontents) via one or more connections 116.

Functions performed by the wireless module 232 may comprise accessingthe security and/or billing server 130 via the wireless connection 134between the wireless module 106 of the system 100 and the wirelessmodule 132 which provides wireless connectivity to the server 130. Theamount of bandwidth needed for communicating billing and/or securityinformation over the connections 116 and 134 may be small relative tothe amount of bandwidth needed for the broadcast signals 136.Accordingly, in an example implementation, the module 226 may utilize,for example, 4^(th) generation protocols such as LTE whereas thewireless module 232 may utilize, for example, 2.5 or 3^(rd) generationprotocols such as EDGE, HSPA, or EVDO.

The gateway 214 may be an implementation of module 112 described above.Functions performed by the gateway 214 may comprise reception,processing, and transmission of data. The gateway 214 may transmitand/or receive data to and/or from the system 100 (via cable(s) 114),the WAN 120 (via WAN connection 126), and/or one or more client devices122 (via one or more connections 234). For data from the module 228 to aclient device 122, the gateway 214 may recover the data from Ethernetframes received over the cable(s) 114 and output the data to the clientdevice 122. For data from the client device 122 and/or gateway 114 tothe module 228, the gateway 214 may encapsulate the data in one or moreEthernet frames and output the frames onto the cable(s) 114. For databetween the WAN 120 and the module 228, the gateway 214 may perform OSIlayer-2 switching and/or OSI layer-3 routing. Although theimplementation shown in FIG. 2 uses wired connections between thegateway 214 and module 228, and between the gateway 214 and WAN 120,other may utilize wireless connections. Although the gateway 214 isdepicted as separate from the system 100, in other implementations atleast a portion of the system 100 may reside in and/or be implemented bythe gateway 214.

In operation, the IP-LNB module 224 may process received satellitesignals to recover content carried on one or more satellite channels. Inan example implementation, content on one or more of the channels may beformatted for consumption by mobile devices. The content may be conveyedto the routing module 230. Additionally or alternatively,mobile-formatted content received from the gateway 214 (such content mayhave, for example, originated in a digital video recorder of the gateway214 and/or been received via the WAN 120) may be conveyed to the routingmodule 230 via the Ethernet transceiver 228. The routing module 230 mayconvey the mobile-formatted content to the small-cell basestation module226.

The system 100 may allocate the content among frequencies that areavailable for transmitting the content. For example, where the contentcomprises a plurality of television networks, each network may bebroadcast on a different frequency according to an EPG provided to thesystem 100 (e.g., by the satellite 102 and/or by the server 103).Similarly, where the content comprises a plurality of programs, eachprogram may be broadcast on a different frequency according to an EPGprovided to the system 100.

The mobile device 110 within the coverage area of the basestation module226 may request satellite content (e.g., a particular TV network orprogram) via the connection 116. In response to the request for content,the system 100 may relay information between the mobile device 110 andthe server 130 to enable the server 130 to verify that the mobile device110 is authorized to receive the requested content, and to provideinformation to the server 130 so that that an account associated withthe mobile device 110 can be billed for the requested content and/or forthe bandwidth utilized in receiving the content. The system 100 maycommunicate with the server 130 via the connection 134. Additionally oralternatively, the system 100 may communicate with the server 130 viathe module 228, cable 114, gateway 214, and WAN 120.

Upon the server 130 determining that the mobile device 110 is authorizedto receive the content that it is requesting, decryption/descramblingkeys, an EPG, and/or other information necessary for receiving therequested content may be transmitted to the device 110 via connections134 and 116. The mobile device 110 may then tune to the frequency of thedesired content, receive the broadcast content, descramble and/ordecrypt the received content, and present the content to its user.

In this manner, for satellite content received via the IP-LNB 224, suchsatellite content may be delivered to the mobile device 110 without thecontent having to traverse the WAN 120 or the connection 126. Thus, ininstances that the system 100 communicates with the server 130 viaconnection 126 and WAN 120, satellite content may be delivered to themobile device 110 while only adding a small amount of billing and/orsecurity traffic to the WAN 120. Moreover, in instances that the system100 communicates with the server 130 via connection 134, satellitecontent may be delivered to mobile device 110 without putting any loadon the connection 126 or WAN 120, thus enabling delivery of thesatellite content even when the broadband connection 126 and/or WAN 120are unavailable.

In an example implementation, the mobile device 110 may belong to afirst satellite subscriber and the satellite reception assembly 302 maybe installed at the home of a second satellite subscriber. Thus, aspectsof the present disclosure may enable the first subscriber to receivesatellite content to which he has subscribed via another subscriber'ssatellite reception assembly.

FIG. 3 depicts an example implementation of the system of FIG. 1 inwhich the system comprises a basestation such as, for example, amacrocell basestation. In FIG. 3, the system 100 includes a basestation306 and a satellite reception assembly 302 that, in turn, comprises asubassembly 304. In the example implementation shown in FIG. 3, thecombination of the wireless module 232 and the basestation 306 may be animplementation of the wireless module 106 described above. Similarly,for example, the routing module 330 may be an implementation of therouting module 124 described above, the wireless transceiver 232 may beas described above, the module 228 may be as described above, and themodule 112 may be as described above. The routing module 330 may beoperable to selectively route data and/or signals between the modules224, 232, 228, and the basestation 306.

Operation may be substantially similar to operation of theimplementation described with respect to FIG. 2.

FIG. 4A is a diagram depicting a region of a single frequency networkfor broadcasting to mobile devices. The region 400 (indicated by theheavy dashed line) comprises coverage areas 402 ₁-402 ₅ (indicated bythe thin dashed lines), each of which is associated with an instance ofthe system 100. For simplicity of illustration, it is assumed thecoverage area for two-way communications (e.g., connection 116) is thesame as the broadcast coverage area (e.g., the reach of signals 136),but the invention is not so limited. The systems 100 ₁-100 ₅ may residein various locations such as on subscriber homes, on cellular towers, onroadside signs, etc. Although the region shown in FIG. 4A comprises fiveinstances of the system 100, a region is not restricted to anyparticular number of instances of the systems 100.

Each of the systems 100 ₁-100 ₅ may be synchronized to a reference clock(e.g., a GNSS clock) and may be locked to a frequency reference signal(e.g., a GNSS signal or any other signal available to each of thesystems 100 ₁-100 ₅). Additionally, each of the systems 100 ₁-100 ₅ maybroadcast data (e.g., media content) according to an EPG. The EPG maydesignate each of the systems 100 ₁-100 ₅ as belonging to region 400 andmay designate which content (e.g., programs and/or TV networks) is to betransmitted on which frequency bands in region 400. Accordingly, each ofthe systems 100 ₁-100 ₅ may simultaneously (or as nearly so as possiblegiven tolerances of components) broadcast a particular program on aparticular frequency band. The device 110, therefore, may roamthroughout the region 400 while receiving the particular program on theparticular frequency without regard to which of the systems 100 ₁-100 ₅the program is being received from any given time instant. When thedevice 110 is in a location where coverage areas overlap, the signalsmay simply appear as multipath from a single source and may be processedas such.

FIG. 4B is a diagram depicting multiple regions of a single frequencynetwork for broadcasting to mobile devices. Shown are regions 450 a and450 b, each of which may be substantially similar to the region 400described with reference to FIG. 4A. The region 450 a comprises systems100 ₆-100 ₈ each of which may be synchronized to a reference clock andwhich may be phase and/or frequency locked to a reference signal.Similarly, the region 450 b comprises systems 100 ₉-100 ₁₂ each of whichmay be synchronized to a reference clock and phase and/or frequencylocked to a reference signal. In some instances, the reference clockutilized in the region 450 a may be the same as the reference clockutilized in the region 450 b. In other instances, the reference clockutilized in region 450 a may be a different clock than the referenceclock utilized in the region 450 b. In some instances, the referencesignal utilized in the region 450 a may be the same as the referencesignal utilized in the region 450 b. In other instances, the referencesignal utilized in region 450 a may be a different signal than thereference signal utilized in the region 450 b.

In an exemplary implementation, an EPG distributed to each of thesystems 100 ₆-100 ₁₂ may instruct the systems 100 ₆-100 ₈ in region 450a to transmit first content (e.g., a first set of programs and/or TVnetworks) on a first one or more frequency bands and instruct thesystems 100 ₉-100 ₁₂ in the region 450 b to transmit second content(e.g., a second set of programs and/or TV networks) on a second one ormore frequency bands. In instances where the same frequency bands areavailable the first set of frequency bands may be the same as the secondset of frequency bands, otherwise the first set may comprise one or morefrequency bands not in the second set and/or vice versa. Which contentis transmitted in each of the regions 450 a and 450 b may be determined,for example, based on subscriber preferences in the regions, based onlocal television networks available in those regions, based contentpopularity in the regions, based on advertisers targeting one or both ofthe regions, etc.

FIG. 5 is a flowchart illustrating example steps for delivering data tomobile devices via a single frequency network. The steps begin with step502 in which each of the systems 100 in each of the regions of the SFNsynchronize to a reference clock and phase and/or frequency lock to areference signal designated for use (e.g., by a satellite provider) intheir respective regions. In step 504, the systems 100 beginbroadcasting content according to an EPG. In step 506, a mobile device110 enters the coverage area of a system 100 that is part of a SFNregion (e.g., the coverage area 402 ₁ of the system 100 ₁ in FIG. 4B)and connects to the system 100 (e.g., establishes a connection 116). Instep 508, the device 110 requests access to content being broadcast bythe system 100. In step 510, it is determined whether the device 110 isauthorized to access the content (e.g., determined whether the device110 has an active subscription). Such a determination may, for example,be made by the server 130 using information received from the device 110via the system 100 and/or via another network path (e.g., cellularconnection) not involving the system 100. The determination of whetherthe mobile device 110 is authorized may be communicated from the server130 to the system 100 to instruct the system 100 as to whether todeliver the content or not. Accordingly, if the server 130 informs thesystem 100 that the device 110 is not authorized to access the content,then in step 520 the request is denied.

Returning to step 510, if the device 110 is authorized to access thecontent, then, in step 512, descrambling/decryption keys and/or otherinformation for receiving the content (e.g., information about thefrequency band on which the content is being broadcast) are communicatedto the device 110 from the server 130 via a network path which may ormay not include the system 100. In step 514, the device tunes to thefrequency band that is carrying the desired content, receives anddecrypts/descrambles the content, and presents the content to its user.In step 516, the device roams into a different coverage area of the sameregion. Reception of the content is unaffected by this movement sincethe system 100 associated with the new coverage area transmitting thesame content at the same time on the same frequency.

FIG. 6 is a block diagram of an example mobile device operable toreceive data broadcast on a single frequency network. Shown is anexample implementation of the mobile device 110 that comprises aprocessing module 602, a memory module 604, an input/output module 606,and a wireless module 608.

The processing module 602 may be operable to execute lines of code(e.g., code corresponding to an operating system and/or one or moreapplications programs) to effect operation of the electronic device 100.Such operation may include receiving broadcast content via the wirelessmodule 608, processing the received content, and presenting the contentto a user via the I/O module 608.

The memory module 604 may comprise volatile and/or non-volatile memorywhich stores, for example, general data, configuration parameters,program code, and/or run-time data generated by the processing module602 while executing program code. In an example embodiment, the memorymodule 604 may be distributed among various components of the device 100and may be utilized for mass storage and/or buffering of content.

The input/output (I/O) module 120 may enable a user to interact with theelectronic device 100. In this regard, the I/O module 120 may supportvarious types of inputs and/or outputs, including video, audio, and/ortext. I/O devices and/or components, external or internal, may beutilized for inputting and/or outputting data during operations of theI/O module 120. The I/O module 120 may comprise, for example, control(s)(e.g., hard buttons and/or a touchscreen), a microphone, and speaker(s).

The wireless module 102 may implement one or more layers of one or morewireless protocol stacks to enable communication over a connection suchas the connection 116 and to receive broadcast content from a system100. The wireless module 102 may, for example, perform packetization,de-packetization, encoding, decoding, encrypting, decrypting,modulation, demodulation, upconversion, downconversion, etc.

In an example implementation, the wireless module 102 may be operable tocommunicate on multiple frequency bands. For example, the connection 116may be on a first one or more frequency bands but broadcast content froma system 100 may be on a second one or more frequency bands.

In an example implementation, the wireless module 102 may be operable tocommunicate on frequency bands licensed by disparate service providers.For example, the connection 116 may be on one or more first frequencybands and in adherence with protocols used by a first service provider(e.g., a cellular provider) and broadcast content may be received from asystem 100 on one or more second frequency bands and in adherence withprotocols used by a second service provider (e.g., a satellite serviceprovider).

FIG. 7 is a flowchart illustrating example steps for delivery of contentto a mobile device via a single frequency network. The example stepsbegin with step 702 in which the mobile device 110 enters a broadcastcoverage region 400. In step 704, the mobile device requests access tocontent broadcast by the systems 100 ₁-100 ₅. In step 706, it isdetermined (e.g., by server 130) whether the device 110 is authorized toaccess the requested content (e.g., determined whether the device 110has an active subscription). If the device 110 is not authorized toaccess the requested content, then in step 520 the mobile device 110receives a denial of its request.

Returning to step 706, if the device 110 is authorized to receive therequested broadcast content, then, in step 710, descrambling/decryptionkeys and/or other information for receiving the content (e.g.,information about the frequency band on which the content is beingbroadcast) are received by the device 110 (e.g., from the server 130 viathe system 100 and/or from the server via another connection notinvolving the system 100). In step 712, the mobile device tunes thewireless module 608 to the frequency band of the requested content, asdetermined based on the information received in step 710. In step 714,the wireless module 608 receives the broadcast content, processes, andpresents it to a user via the I/O module 606.

FIG. 8 depicts a plurality of satellite reception assemblies that areoperable to participate in a single frequency network. Shown aresatellite reception assemblies 100 ₁₃-100 ₁₉, and a mobile device 110making a trip from location 802 to location 804. Also shown are coverageareas 800 ₆, 800 ₁₅, and 800 ₁₇ corresponding, respectively, tosatellite reception assemblies 100 ₁₃, 100 ₁₅, and 100 ₁₇. The mobiledevice 110 may desire to receive particular content as it makes the tripfrom 802 to 804.

In an example implementation, the particular content may be selectedfrom a list of particular content that is available and is alreadyscheduled to be transmitted be each of the assemblies 100 ₁₃-100 ₁₉during the trip. In such an implementation, the mobile device 110 may,after being validated, receive keys for decrypting the broadcast contentand then, during the trip, tune to the broadcast content similar to themanner in which a television or set-top-box may tune to a conventionalcable or satellite television channel.

In another example implementation, the particular content may not bescheduled for broadcast by all satellite reception assemblies 100 ₁₃-100₁₉. Rather, at any given time, the particular content may be broadcastonly by the satellite reception assembly 100 _(i) (i being an integerbetween 13 and 19) corresponding to the coverage area 800 _(i) that themobile device 110 is in at that time. The assemblies 100 ₁₃-100 ₁₉(and/or a network management entity that coordinates the assemblies 100₁₃-100 ₁₉) may determine which coverage area the mobile device 110 is inbased on two-way communications between the mobile device 110 and themodule 106 of the satellite reception assembly 100 _(i). Alternatively,which coverage area the mobile device 110 is in may be determined basedon information communicated from the mobile 110 to the assemblies 100₁₃-100 ₁₉ (and/or an SFN management entity) via a cellular link to aconventional basestation and a backhaul network. In this manner,efficient use of resources in the assemblies 100 ₁₃-100 ₁₉ may beachieved. For example, where the device 110 is in coverage area 800 ₁₃and is the only device desiring the particular content, the assembly 100₁₃ may broadcast the particular content but other assemblies 100 ₁₄-100₁₉ may not (thus freeing up resources in assemblies 100 ₁₄-100 ₁₉ forbroadcasting content that is actually desired in their respectivecoverage areas).

Information which may be communicated from the device 110 to the SFN andmay be used for determining which satellite reception assemblybroadcasts which content at which times may include, for example, GNSScoordinates of the mobile device 110, a velocity of the mobile device110, and/or a planned route of the mobile device 110 (e.g., uploaded tothe backhaul network upon being calculated by a map application of themobile device 110). By using such information, movement of the device110 from one coverage area to another may be predicted such that themobile device 110 may receive the content seamlessly.

Other implementations may provide a non-transitory computer readablemedium and/or storage medium, and/or a non-transitory machine readablemedium and/or storage medium, having stored thereon, a machine codeand/or a computer program having at least one code section executable bya machine and/or a computer, thereby causing the machine and/or computerto perform the steps as described herein for a single frequency networkfor broadcasting to mobile devices.

Accordingly, the present method and/or system may be realized inhardware, software, or a combination of hardware and software. Thepresent method and/or system may be realized in a centralized fashion inat least one computing system, or in a distributed fashion wheredifferent elements are spread across several interconnected computingsystems. Any kind of computing system or other system adapted forcarrying out the methods described herein is suited. A typicalcombination of hardware and software may be a general-purpose computingsystem with a program or other code that, when being loaded andexecuted, controls the computing system such that it carries out themethods described herein. Another typical implementation may comprise anapplication specific integrated circuit or chip.

The present method and/or system may also be embedded in a computerprogram product, which comprises all the features enabling theimplementation of the methods described herein, and which when loaded ina computer system is able to carry out these methods. Computer programin the present context means any expression, in any language, code ornotation, of a set of instructions intended to cause a system having aninformation processing capability to perform a particular functioneither directly or after either or both of the following: a) conversionto another language, code or notation; b) reproduction in a differentmaterial form.

While the present method and/or system has been described with referenceto certain implementations, it will be understood by those skilled inthe art that various changes may be made and equivalents may besubstituted without departing from the scope of the present methodand/or system. In addition, many modifications may be made to adapt aparticular situation or material to the teachings of the presentdisclosure without departing from its scope. Therefore, it is intendedthat the present method and/or system not be limited to the particularimplementations disclosed, but that the present method and/or systemwill include all implementations falling within the scope of theappended claims.

1. A method performed by one or more circuits of a satellite receptionassembly, the method comprising: receiving a satellite signal;recovering content carried in said satellite signal; and broadcasting afirst signal carrying said content for reception by one or more mobiledevices.
 2. The method of claim 1, wherein said satellite receptionassembly is mounted to the residence of a satellite subscriber.
 3. Themethod of claim 1, wherein said first signal carrying said content isfrequency locked to a reference signal that is available to saidsatellite reception assembly and to one or more other satellitereception assemblies.
 4. The method of claim 3, wherein said referencesignal is a GNSS signal.
 5. The method of claim 1, wherein said firstsignal carrying said content is synchronized to a reference clock thatis available to said satellite reception assembly and to one or moreother satellite reception assemblies.
 6. The method of claim 5, whereinsaid reference clock is a GNSS clock.
 7. The method of claim 1,comprising communicating with said one or more mobile devices to providea key to said one or more mobile devices, said key being required fordescrambling and/or decryption of said content carried in said signal.8. The method of claim 1, wherein said satellite reception assembly isselected, from among a plurality of satellite reception assemblies, forsaid broadcasting said signal based on one or more of: a planned route,a current location, or a current velocity of said one or more mobiledevices.
 9. A system comprising one or more circuits for use in asatellite reception assembly, said one or more circuits being operableto: receive a satellite signal; recover content carried in saidsatellite signal; and broadcast a first signal carrying said content forreception by one or more mobile devices.
 10. The system of claim 9,wherein said satellite reception assembly is mounted to the residence ofa satellite subscriber.
 11. The system of claim 9, wherein said firstsignal carrying said content is frequency locked to a reference signalthat is available to said satellite reception assembly and to one ormore other satellite reception assemblies.
 12. The system of claim 11,wherein said reference signal is a GNSS signal.
 13. The system of claim9, wherein said first signal carrying said content is synchronized to areference clock that is available to said satellite reception assemblyand to one or more other satellite reception assemblies.
 14. The systemof claim 13, wherein said reference signal is a GNSS signal.
 15. Thesystem of claim 9, wherein said one or more circuits are operable tocommunicate with said one or more mobile devices to provide a key tosaid one or more mobile devices, said key being required fordescrambling and/or decryption of said content carried in said signal.16-22. (canceled)
 23. The system of claim 11, wherein: said one or moreother satellite reception broadcast a second signal carrying saidcontent; and said second signal is frequency locked to said referencesignal.
 24. The system of claim 23, wherein a coverage area of saidfirst signal carrying said content overlaps with a coverage area of saidsecond signal carrying said content.
 25. The system of claim 13,wherein: said one or more other satellite reception broadcast a secondsignal carrying said content; and said second signal is synchronized tosaid reference clock.
 26. The system of claim 25, wherein a coveragearea of said first signal carrying said content overlaps with a coveragearea of said second signal carrying said content.